A managed access system for mobile wireless devices (mwds) in a facility that is geographically within a wireless communications network includes a plurality of antennas at the facility. radio equipment is coupled to the antennas. A management access controller cooperates with the radio equipment to communicate with a given mwd within the facility, block outside communications via the wireless communications network when the given mwd is an unauthorized mwd, and provide outside communications when the given mwd is an authorized mwd. The management access controller cooperates with at least one device to determine a change in the wireless communications network and implement a corresponding change in the radio equipment.
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1. A managed access system for mobile wireless devices (mwds) in a facility, the facility being geographically within a wireless communications network, the managed access system comprising:
a plurality of directional antennas arranged at the facility;
radio equipment coupled to said plurality of directional antennas;
a plurality of monitoring devices for the wireless communications network; and
a management access controller cooperating with said radio equipment to communicate with a given mwd within the facility, block outside communications via the wireless communications network when the given mwd is an unauthorized mwd, and provide outside communications when the given mwd is an authorized mwd;
said management access controller cooperating with said plurality of monitoring devices to determine a change in the wireless communications network and implement a corresponding change in said radio equipment.
23. A method for operating a managed access system for mobile wireless devices (mwds) in a facility, the facility being geographically within a wireless communications network, the managed access system comprising a plurality of directional antennas arranged at the facility, radio equipment coupled to the plurality of antennas, and a plurality of monitoring devices for the wireless communications network, the method comprising:
operating a management access controller to
cooperate with the radio equipment to communicate with a given mwd within the facility, block outside communications via the wireless communications network when the given mwd is an unauthorized mwd, and provide outside communications when the given mwd is an authorized mwd, and
cooperate with the plurality of monitoring devices to determine a change in the wireless communications network and implement a corresponding change in the radio equipment.
16. A management access controller for a managed access system for mobile wireless devices (mwds) in a facility, the facility being geographically within a wireless communications network, the managed access system comprising a plurality of directional antennas arranged at the facility, radio equipment coupled to the plurality of directional antennas, and a plurality of monitoring devices for the wireless communications network, the management access controller comprising:
a processor and a memory coupled thereto to
cooperate with the radio equipment to communicate with a given mwd within the facility, block outside communications via the wireless communications network when the given mwd is an unauthorized mwd, and provide outside communications when the given mwd is an authorized mwd, and
cooperate with the plurality of monitoring devices to determine a change in the wireless communications network and implement a corresponding change in the radio equipment.
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The present invention relates to communications systems, and more particularly, this invention relates to a managed access system for a mobile wireless device in a facility.
Over the last twenty years, the wireless telecommunications market has seen tremendous growth, including the use of contraband mobile wireless devices in correctional facilities or unauthorized use of such devices in other secure facilities, such as government offices. These devices are often smuggled into correctional facilities or other secure facilities and made available to unauthorized users, including inmates, which may use them to continue criminal enterprises outside the facility, threaten witnesses, and harass victims. Use of such devices may also pose a continued security risk in a correctional facility because the inmates may use them to coordinate inmate riots or direct retribution on guards, police or government officials.
It is difficult to prevent the smuggling of mobile wireless devices into correctional or other secure facilities because of commercial technology improvements and the variety of smuggling techniques available to unauthorized users and inmates. The improvements in commercial technology have reduced the size of mobile wireless devices and eased the challenges of smuggling or even accidentally carrying a mobile wireless device into a facility. Also, the accessibility of less expensive mobile wireless devices has placed these devices within the financial reach of most inmates or other unauthorized users. Though institutional security measurements are in place to attempt to prevent the smuggling of contraband into correctional facilities, the range of smuggling methods available to deliver contraband mobile wireless devices into the facility makes it difficult or even impossible to stop the flow. Inmates may coordinate smuggling efforts with visitors who move in and out of the facilities. Visiting friends and family are commonly involved in introducing contraband. Smugglers even employ methods such as throwing handsets over facility walls or fences, or concealing them in packages sent to the facility. Physical security measures alone may not be sufficient to prevent the introduction of mobile wireless devices into correction facilities or other secure facilities.
As smuggling cannot be reasonably prevented, alternative methods have been developed that focus on finding mobile wireless devices that are already inside the facilities. For example, some systems detect and locate contraband devices, which can then be confiscated. Often these systems include fixed, portable and handheld detection systems, but they can be expensive to acquire and require significant effort and personnel cost to use effectively. Their operational efficacy also is related to the effort that the facility invests in time, training, and technology. An increased effort from the facility may improve results, but it may also increase operational costs.
Because a cell phone's benefit to the user is its ability to access the commercial wireless network, denying the cell phone access to the wireless network may be a better approach to reduce the risks posed by contraband cell phones and other mobile wireless devices. The device is benign without access to the commercial wireless network. A range of technology based approaches have been developed and are available to limit an unauthorized device's access to the commercial wireless network. These approaches include jammer technologies and access management approaches. There are several types of jammers, but they are typically designed to disrupt the communications of the device with the wireless communications network. One type of access management approach is a Managed Access System (MAS), which employs a private wireless network within a facility to provide wireless network access to authorized cell phones within the system's range. Authorized devices are provided access to voice and data services while unauthorized devices are denied access.
Another type of system, an Access Denial Service (ADS) works cooperatively with the commercial wireless network to deny access to unauthorized devices within a facility. An ADS system uses the interaction between cell phones and the network to determine if the cell phone is within a facility or not. When a cell phone is detected within the facility, the carrier is notified and if the device is not authorized for operation in the facility, it is prevented from future access to the wireless network by the carrier.
There are drawbacks to such systems. Geolocation devices alone will not provide sufficient detail on the device identification to enable action by the commercial service provider. Managed Access Systems may provide insufficient information to determine the location of a cellular device that has registered to their network. They can typically only identify that a device has attached, what has attached, and when it has attached. At best, it can identify which sector of a distributed antenna system the attachment has occurred. The system typically needs to operate on a persistent basis using fixed location, autonomous sensors.
A managed access system for mobile wireless devices (MWDs) in a facility that are geographically within a wireless communications network comprises a plurality of antennas arranged at the facility, radio equipment coupled to the plurality of antennas, and at least one monitoring device for the wireless communications network. A management access controller cooperates with the radio equipment to communicate with a given MWD within the facility, block outside communications via the wireless communications network when the given MWD is an unauthorized MWD, and provide outside communications when the given MWD is an authorized MWD. The management access controller cooperates with the at least one monitoring device to determine a change in the wireless communications network and implement a corresponding change in the radio equipment.
Each of the plurality of antennas comprises a directional antenna that may be arranged around a periphery of the facility. The radio equipment may comprise a plurality of picocell radios, each coupled to a respective directional antenna. The management access controller may implement the corresponding change in the radio equipment as a change in a power level of at least one of the picocell radios. The management access controller may implement the corresponding change in said radio equipment as a change in a communications protocol of at least one of the picocell radios. The management access controller may implement the corresponding change in the radio equipment as a change in a frequency range of at least one of the picocell radios.
The managed access system may comprise at least one MWD geolocation device and the management access controller may cooperate with the at least one MWD geolocation device to locate the given MWD within the facility. The at least one MWD geolocation device may comprise a plurality of external geolocation devices arranged around the periphery of the facility. The at least one MWD geolocation device may comprise a plurality of internal geolocation devices arranged within the periphery of the facility.
The change in the wireless communications network may comprise addition of a rogue base station and the management access controller is configured to block communications with the rogue base station. The management access service may provide outside communications when the given MWD is an authorized MWD using a Session Initiation Protocol (SIP). The management access controller may provide outside communications when the given MWD is an authorized MWD via another network other than the commercial wireless network. The management access service may provide outside communications when the given MWD is an authorized MWD via the Public Switched Telephone Network (PSTN). The management access service may provide outside communications when the given MWD is an authorized MWD via an Internet Protocol (IP) network. The radio equipment is operable according to at least one of an LTE, CDMA, UMTS and GSM protocol.
A management access controller is for a managed access system for mobile wireless devices (MWDs) in a facility that is geographically within a commercial wireless network. The managed access system comprises a plurality of directional antennas arranged around a periphery of the facility, radio equipment coupled to the plurality of directional antennas, and a monitoring device for the wireless communications network. The management access controller comprises a processor and a memory coupled thereto to cooperate with the radio equipment to communicate with a given MWD within the facility, block outside communications via the commercial wireless network when the given MWD is an unauthorized MWD, provide outside communications when the given MWD is an authorized MWD, and cooperate with the monitoring device to determine a change in the commercial wireless network and implement a corresponding change in the radio equipment.
A method for operating a managed access system for mobile wireless devices (MWDs) in a facility that is geographically within a wireless communications network includes the managed access system that comprises a plurality of directional antennas arranged around a periphery of the facility, radio equipment coupled to the plurality of directional antennas, and a monitoring device for the wireless communications network. The method comprises operating a management access controller coupled to cooperate with the radio equipment to communicate with a given MWD within the facility, block outside communications via the commercial wireless network when the given MWD is an unauthorized MWD, provide outside communications when the given MWD is an authorized MWD, and cooperate with the monitoring device to determine a change in the commercial wireless network and implement a corresponding change in the radio equipment.
Other objects, features and advantages of the present invention will become apparent from the detailed description of the invention which follows, when considered in light of the accompanying drawings in which:
Different embodiments will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments are shown. Many different forms can be set forth and described embodiments should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope to those skilled in the art. Like numbers refer to like elements throughout.
The managed access system, in accordance with a non-limiting example, permits communications from authorized mobile wireless devices and detects and disrupts wireless communications from unauthorized or contraband mobile wireless devices within a protected facility, such as a correctional facility. The different embodiments will be described relative to a correctional facility, but it should be understood that the managed access system, in accordance with a non-limiting example, may be used in many different facilities, including non-secure and secure buildings such as government offices, military compounds, corporate workplaces, and other areas where managed access systems may be implemented to detect and disrupt wireless communications from contraband and unauthorized mobile wireless devices, but permit authorized users to communicate either internally within the facility or with an outside commercial communications network.
The managed access system as will be described can be scaled to address a wide variety of wireless communication threats within a facility and mitigate the threat presented by contraband cellular and other unauthorized mobile wireless devices. The managed access system may be used to prohibit contraband and other unauthorized mobile wireless devices from accessing commercial voice and data networks. The system may provide a full-spectrum cellular service so that every mobile wireless device within the facility, regardless of commercial carrier or technology, e.g., as 4G LTE, 3G LTE, or other communication standards, is connected to the managed access system for both voice and data network communications rather than connected to any commercial networks.
Because local commercial cellular coverage varies from facility to facility, including a) the number of carriers, b) the technology mix of 2G, 3G and 4G standards, and c) the frequencies used by local carriers, the managed access system is built upon a modular system architecture and allows the communications technology mix to be optimized for any facility. For example, the managed access system may be reconfigured to address changes to the local communications environment and facilitate upgrades for future cellular and other communications technologies, such as 5G and beyond. The managed access system includes support for WiFi (802.11X) and other conventional radio technologies, including push-to-talk radios that can be added to the cellular core functionality to increase the diversity of the types of communications technology that can be detected and disrupted by the system. Drone detection capability may be implemented.
As will be explained in greater detail below, the managed access system is implemented after an initial site survey is performed where on-site data is collected to determine which commercial carriers are in the area and what cellular technologies and frequency bands cover the particular facility where the managed access system will be implemented. The collected data is used to determine the technology mix and frequency coverage necessary to provide effective cellular mitigation within the facility. To implement the managed access system, radio frequency (RF) propagation data for the facility is collected and provides empirical measurements to understand how signals propagate throughout the facility. This propagation data is used to design a Distributed Antenna System (DAS) using directional antennae and mitigate cellular access coverage from within the facility using a managed access system RF “bubble” over the facility. The empirical propagation data is used to predict signal levels in and around the facility. A cellular elevation survey is completed to determine the type and scope of infrastructure for improvements to support the managed access system RF “bubble.” Once installed, the system is maintained and monitored, including continuous system alarm monitoring.
Referring now to
Referring now to
The management access server 12 interoperates with an Ethernet switch 52 and includes a network firewall 54, physical security 56, e.g., locks for the rack 36, a GPS time server 58, GPS splitter 60, power distribution circuits 62 and UPS (uninterrupted power supply) 64. The management access server 12 interoperates through an electrical-to-optical (E/O) interface 66 to at least one external geolocation device that is formed as an external geolocation sensor array 70 and includes wideband remote sensors 72 as external geolocation devices, which are operable for both cellular and non-cellular communications to detect those signals in the facility 44. These wideband sensors 72 are arranged around the periphery of the facility in a non-limiting example, and may communicate using an Ethernet connection via optical/electrical converters 74 and interconnect via an optical fiber bundle to the electrical/optical interface 66 and the management access server 12.
An internal location sensor array 80 is arranged within the periphery of the facility 44, and in an example, located within a building. Internal geolocation devices are sensors 82 that may connect via wireless link to each other and via Ethernet to the management access server 12.
The system 10 includes cellular environmental monitoring 86 of the wireless communications network and includes a remote cellular scanner 88 that connects via Ethernet connection to the management access server 12. The monitoring device 86 determines a change in the wireless communications network as a commercial network, for example, and implements a corresponding change in the radio equipment 40 such as a change in the power level of one of the picocell radios, a change in communications protocol, and/or a frequency change. Such protocols could include data and address formats, address mapping changes, routing changes, change in acknowledgement systems, change in direction of data flow, and changes in sequence and flow control.
It is possible to change different communication standards, including TCP/IP models and protocol layering with different encapsulation data formats. Changes in software layering are possible. Different network protocols can be used. Power levels may be changed to increase or decrease the power in towers connected to radio equipment 40 and directional antennas 46. Frequency changes may occur with changes in protocol or depending on what occurs at the wireless communications network 45 such as commercial networks. Frequencies can vary depending on what other outside communication networks are used or other transmitters and radio sources are monitored and determined near the facility to adjust HF, VHF, UHF, and other frequency ranges, including those in the cellular commercial band. Different carriers have different frequencies, including frequency bands such as 3G, 4G, GSM, IS-95 as CDMA, 3G, and 5G. Different bands include the 700, 800, 850, 1400, PCS, AWS, and BRS/EBS frequency bands. These are non-limiting examples only. Power may also depend on the type of cell such as use of a picocell that is a small cellular base station covering a small area such as a shopping mall or train station. The system allows an authorized user to connect into a commercial carrier network that provides roaming services so that even if an authorized user of a mobile wireless device is not able to connect directly to their carrier they use on their mobile wireless device, it is possible to connect into a commercial carrier network that could be the same as the wireless communications network around a facility or a different network that provides roaming services. The system is deployable on cruise ships, oil platforms, and in mines as non-limiting examples.
An example could be a change in the wireless communications network 45 such as the addition of a rogue base station. The management access server 12 would be changed and configured to block communications from any mobile wireless device (MWD) 42 with that rogue base station. The management access server 12 also may provide outside communications when the given mobile wireless device is an authorized mobile wireless device using a Session Initiation Protocol (SIP) and provide outside communication when the given mobile wireless device is an authorized mobile wireless device via another network other than the commercial wireless network, such as a land-line connection via the Public Switched Telephone Network (PSTN). Another network could be used, such as an Internet Protocol (IP) network.
The managed access system 10 provides both the signaling and services for all cellular devices within the facility 44 and uses strategic channel selection, parameter configuration, and signal dominance. For example, the management access server 12 strategically selects channels used to establish the voice and data network within the facility 44 and may configure key parameters of the system 10 to attract cellular and other mobile wireless devices 42 to the system while making the commercial cellular network 45 unavailable. This can be accomplished using a) signal dominance, such as delivering a higher power, b) delivering a better quality signal, and c) adjusting other parameters relative to the commercial carrier network 45 to help ensure that the managed access system 10 provides a cellular voice and data network that is the strongest and most attractive signal within the facility as seen by cellular or other mobile wireless devices 42 and block any device from connecting directly to the commercial communications network 45. The system 10 is effective for use with smart phones, tablets, cell phones, modems and other types of wireless devices that use cellular technology and other radio frequency communications to access voice or data networks.
As noted before, because commercial cellular carrier coverage varies between different facilities, to optimize the system for a particular facility, a survey of the cellular network in and around a facility 44 is first completed. The collected data determines the technology mix and frequency coverage necessary to provide the effective cellular mitigation within the facility 44. Using this data, the RF “bubble” is created around the facility using the distributed antenna system 14 and its individual directional antennas 46. Inside the RF bubble, all cellular and other mobile wireless devices 42 connect to the management access server 12 while outside the RF “bubble,” cellular and other mobile wireless devices operate as normal by connecting to the available commercial communications network 45. Use of the management access server 12 and radios 40 connected to the directional antennas 46 allow the size and shape of the RF bubble to be contoured and tailored to the facility 42 by selecting specific antenna locations and RF power levels for each unique signal.
As noted before, it is possible to have a roaming partnership with commercial carriers to give the flexibility to use authorized mobile wireless devices 42 in their fullest commercial capability. Nothing has to change with the billing involved with the commercial carrier. The management access server 12 may provide the device either all, some, or none of the services inside the “bubble” on a case-by-case basis. The system may push a mobile wireless device 42 to a SIP, a voice connection, or PSTN and move from the cellular network as noted before.
Also, the management access server 12 may cooperate with the at least one MWD monitoring device 88 to determine whether the radio equipment 40 and at least one MWD monitoring device 88 both detect the given mobile wireless device and may generate an indication or alarm when one and not the other of the at least one MWD monitoring device and radio equipment detects the given MWD. The system 10 is tiered so that the indication or alarm could indicate that the MWD is outside the facility and beyond the fence line, for example, when the monitoring device 88 detects the device, but not the radio equipment 40.
The at least one MWD geolocation device is operable for both cellular and non-cellular communications whether it is internal or external, and in one embodiment, includes a plurality of external geolocation devices 72 forming an external sensor array and arranged around the periphery of the facility as the wideband remote sensors. These devices as the sensors 72 may operate based on the time-difference-of-arrival signals. Another series of MWD geolocation devices include a plurality of internal geolocation devices 82 as internal sensors and arranged within the periphery of the facility, and in an example, within a building (B) as described later. The radios 40 may be picocell radios each coupled to a respective directional antenna 46.
The management access server 12 may implement a corresponding change in the radio equipment 40 in response to a change in the wireless communications network 45 of at least one of a change in the power level of at least one of the picocell radios, a change in a communications protocol of at least one of the picocell radios, and a frequency range of at least one of the picocell radios. This allows an RF “bubble” to form around the facility, and which the RF bubble can be maintained and adjusted as necessary. The management access server 12 may provide outside communications when the given MWD 42 is an authorized MWD via another network other than the wireless communications network 45 such as through the Public Switched Telephone Network (PSTN) 244 and/or an Internet Protocol (IP) network such as through an SIP server 242 (
As illustrated, the facility 44 includes at least one monitoring device 88 for the wireless communications network. The management access server 12 may cooperate with the monitoring device 88 to determine a change in the wireless communications network and implement a corresponding change in the radio equipment 40 to adjust the radio equipment and adjust the RF “bubble.” This is advantageous such as when a rogue base station 45b is monitored and determined to be active in causing a change in the RF “bubble” such that the rogue base station communicates with a MWD within the facility. The management access server 12 may block communications with the rogue base station 45b. The management access server 12 may also cooperate with at least one MWD monitoring device 88 to determine whether the radio equipment 40 and at least one MWD monitoring device both detect the given MWD and operate to determine if the system is operating.
The management access server 12 also cooperates with the at least one MWD geolocation device as external or internal sensors 72, 82 to determine that a given MWD is within the facility and compares an identification of the given MWD to a last of authorized MWDs and determine whether a given MWD is unauthorized or authorized. It may coordinate with the wireless communications network 45 to block outside communications when the given MWD is an authorized MWD, provide outside communications via the radio equipment 40 and the wireless communications network 45 when the given MWD is an authorized MWD. It may block the outside communications when the given MWD 42 is an authorized MWD based upon a coordinated access denial with the wireless communications network 45 by allowing the base stations 45a and a service provider 45c of the wireless communications network to prevent communications. As illustrated, a network interface device 280 operates as an in-line ID monitor or filter to the wireless communications network and configured to communicate with MWDs 42 via the radio equipment and compare an identification of a given MWD to a list of authorized MWDs to determine whether the given MWD is authorized or unauthorized. The management access server 12 will filter communications between an unauthorized MWD and the network interface device that is configured to provide communications with the communications carrier. Communications will pass between an authorized MWD and the network interface device. The identification of the given MWD may be an International Mobile Subscriber Identity (IMSI).
After the signal is evaluated for its type and the RSSI measurements collected and a determination has been made the device is non-cellular (block 110), a determination is made whether the device is authorized (block 134) and if not, it is geolocated (block 126). If the device is authorized, then the process ends (block 136).
The Distributed Antenna System (DAS) 14 includes the plurality of directional antennas 46, which in this example are positioned at a height of about 10 meters for this example correctional facility. In one example, twelve (12) directional antennas 46 are used in the example shown in
An example directional antenna 46 is an antenna manufactured and sold by Galtronics under the EXTENT™ tradename such as a model D5778I. These example antennas are designed as 60°/60° narrow beam directional antenna with an operating range of 698-960 MHz and 1695-2700 MHz and adapted as a broadband directional, single-sector MIMO antenna for high-capacity venues. Each directional antenna 46 is connected to a radio 40, which in one example is a picocell commercial radio as noted before and shown diagrammatically in
The distributed antenna system 14 is controlled via the DAS master server 48 by the management access server 12 that includes its main server or radio rack 36 as illustrated in
The management access server 12 with the corresponding DAS master server 48 are contained in a secure facility such as a communications closet on site at the facility 44 and in a cooled location and includes easy power access and a ready optical fiber connection. The directional antennae 46 connect by optical fiber to the DAS master server 48, which includes the appropriate processor, RF interface modules, optical modules, power supply, and UPS as shown in
A block diagram is shown in
A Managed Access Carrier Generator (MACG) may interoperate with the distributed antenna system 14 and is part of the management access server 12 and has multi-carrier transmitter functionality for wireless networks. It generates up to four independently tuned control channels in one of several wireless licensed bands. It is possible to modulate a PN sequence with multiple frequency bands with an RF power output of about 1 watt. It may include various interfaces, including four individual TNC connectors in one example on a back patch panel with a combined carrier single TNC preferred so long as it is individually power controlled. The network may be 10/100 Ethernet TCP/IP with a standard RJ45 on the back panel and use SNMP.
Generated messages may include bit, active channels, temperature, frequency tuning, output power adjustment per channel, channel on or off, soft reset and hard reset. The state of health reports and events may be generated via SNMP messaging with a time sensitive active, temperature, power, radio fault, and VSWR alarm. The distributed antenna system 14 shown in
Referring now to
Using this network security design shown in
As noted before with reference to
An example monitoring device as a remote cellular scanner 88 is a fixed autonomous telecommunications measuring receiver such as manufactured and sold by Gladiator Forensics under the tradename Gladiator 6700. One or more devices may be positioned at the facility 44 in a central or other location at the fence line or other areas. This monitoring device 88 provides layer 3 data for primary bands and technologies except IDEN and WiMax, in an example, although it is possible to provide a monitoring device to also scan IDEN and WiMax. The device or scanner 88 operates at 0-55° C. and uses minimal power. It uses a 9-34 volt DC input and a control connection via USB or WiFi. It is a small package of about 3×6×9 inches in one example. It can be operated manually with single button operation and autonomously scans and measures 2G, 3G, and 4G wireless networks and supports GSM, UMTS, LTE (TDD and FDD), CDMA, and EVDO. Most bands are supported in the frequency range of about 447 MHz to 3.8 GHz with pre-selection up to 8 bands. It includes MIMO downlink characterization. It has a nominal operating power consumption of 40 watts and is small and lightweight at 7 kg and ruggedized to an environmental specification of class 2 vibration and shock. Downconverted RF to IF signals are pre-filtered and passed to a signal processor where the data is collected and processed and sent to the drive application for analysis. It should be understood that other types of monitoring devices may also be used.
Changes to the commercial cellular network 45 may have a significant impact on the performance of the managed access system 10 and/or size and shape of the coverage area, i.e., the RF “bubble” 150. The cellular network monitoring device 88 will examine any commercial carrier cellular network environment, looking for changes in its environment that will impact the performance or coverage area of the managed access system 10. The monitoring system 16 supports most frequency bands and cellular technologies currently in use within the United States, including TD-LTE, LTE-FDD, UMTS, CDMA, 1×RTT, CDMA, EVDO, and GSN.
The monitoring system 16 also regularly surveys the cellular environment at the facility 44 and the results of these surveys are compared to the previously established baseline for that site. A comparison will detect configuration changes to any commercial carrier signals, including changes in transmitted power, alteration of configuration parameters, and changed or any new frequencies, channels or bands that are deployed in the area. Regular monitoring is important because changes to the commercial cellular network 45 will have an impact on the effectiveness of the managed access system's ability to prevent contraband or unauthorized mobile wireless devices from accessing the commercial voice and data networks. This task can be performed daily at the facility 44. Thus, the system 10 is able to mitigate changes in the commercial cellular footprint. The state of health monitoring 22 and system and configuration management 24 (
Cellular
Weekly Reports
Baseline System
System Health Verification
Blocked Call Detail Record
User ID Report
Audit Log Reports
Authorized Number Alert Report
Authorized Number Reports
Authorized Number Expiration Reports
Cellular Environment Current Status
(Threat Assessment)
State of Health Alerts
Over-temperature Alert
Tamper Alert - Rack
Off-line System Components
Internal
Weekly Reports
Localization
System Health Verification
Sensor Array
Cellular/WiFi Event Localization
Report
When a commercial carrier change in the commercial communications network 45 indicates a change is required to the software configuration for the managed access system 10, a file may be pushed electronically to the management access server 12 at the facility 44. Any software upgrades or updates can be coordinated with a designated facility officer or at the network operations center 160 to ensure any potential system operation disruption is coordinated and minimized. Once the update is applied, a repeat survey can be completed to ensure that the event risk has been mitigated and the issue resolved.
If a change in commercial carrier 45 dictates a hardware configuration change in the system 10, the system builder may coordinate with a designated facility office to schedule a site visit and make the prescribed changes. An example could be when the change in cellular coverage indicates an alignment of one or more directional antennas 46 is required or an adjustment should be made to improve signal delivery and compensate for an increased commercial carrier signal level. If a change also indicates a new or additional hardware upgrade is necessary to maintain system performance effectiveness, such as when a new commercial carrier has added coverage to the area, the system builder may develop a proposal for necessary changes and add or upgrade equipment.
As noted before, the monitoring device 88 initially determines the existing commercial coverage site baseline using a cellular site survey. For example,
A preliminary distributed antenna system 14 design is implemented (block 254) and the location, height and directional antenna 46 type are determined based upon the site baseline and the system 10 signal coverage zones established throughout the facility 44. The signal coverage boundary at the facility 44 for the fence and property lines 152, 156 are also calculated. A preliminary distributed antenna system 14 configuration is established.
The preliminary distributed antenna system 14 design is verified and finalized (block 256), followed by an on-site installation with verification and tuning of directional antennas (block 258) and on-site system coverage tuning (block 260). The process ends (block 262).
An example of an external geolocation device or sensor 72 that forms the external geolocation sensor array 70 around the periphery of the facility 44 is an array of sensor devices such as the RFeye array sensor manufactured and sold by CRFS as the RFeye series of sensor devices. These external geolocation devices 72 are arranged around the periphery of the facility such as shown in
Referring to
With angle of arrival sensing, the devices 72 rapidly switch between the directional antenna modules 72c and respond directly to the received RF power. Thus, they are effective with most types of RF transmission. Using angle of arrival, three receiver points ensure geolocation to a small area, even when the target is colinear with two receivers. Results may be limited by the noise floor of the receiver.
With time difference of arrival, the devices 72 use synchronous time domain to determine the relative time of arrival of a signal at different receiver locations. Two monitoring receiver points provide geolocation probability in two dimensions along a hyperbolic curve, while three receiver points provide geolocation probability to a bounded area or point. An advantage is that the processing gain of correlations permits successful geolocation of signals close to or even below the receiver noise floor. Power on arrival uses synchronous frequency domain and is beneficial for those mobile wireless devices 46 that are close to or among different buildings where amplitude comparison will yield sufficient differences. It uses three or more monitoring receiver points.
An internal location sensor array 80 is formed from internal geolocation devices as internal sensors 82 and are arranged within the periphery of the facility. In addition to adding the ability to localize a cellular or other mobile wireless device 42 in and around the buildings on facility grounds, the internal sensor array 80 provides the added capability to detect and estimate the location of WiFi devices in and around the various buildings of the facility 44.
An example internal geolocation sensor 82 is a location-based WiFi and cellular detection and monitoring device manufactured and sold by AirPatrol under the tradename ZoneAware, as a precision location-based services platform. These sensors 82 may interoperate with a ZoneEngine application programming interface, also manufactured and sold by AirPatrol. The sensor 82 location is accurate to within 6 to 50 feet depending on the type of device and their spacing. The sensors 82 may incorporate positioning capabilities using beacons and a Bluetooth standard known as “Bluetooth Low Energy” (BLE) to broadcast messages to other devices within a small tunable radius around the beacon. In one non-limiting example, sensors 82 may be located approximately 65 feet apart with different sensors located on different floors and linked in a mesh network via WiFi or connected via wired Ethernet or Power over Ethernet. The sensors 82 are deployed throughout buildings in the facility, usually on the exterior of the buildings, and at a higher elevation for enhanced security to prevent tampering.
The detection of cellular signals using the managed access system 10 is a layered or tiered approach and focuses on determining which internal or external geolocation sensor 72, 82 detected the signal and at what level the signal was detected. An indication or alert can be placed on the user interface 30 to indicate the sensor or sensors that identified the signal transmission and at what power level. This alert will provide a general location where the mobile wireless devices 42 are located, such as shown in the example of
Detection and accuracy of the localization functionality are dependent on the ability of the sensor 82 to: (1) receive a signal at a sufficient level (often −100 dBm or greater); (2) the construction of the facility being protected; and (3) the placement separation of the sensors themselves. An example placement for sensors 82 is shown in the facility 44 of
In the example of
The managed access system 10 prohibits cellular and other mobile wireless devices within the protected facility 44 from accessing commercial voice and data networks by attracting and providing service to those devices within the facility. The system 10 interacts with each device using industry standard messaging traffic and these device interactions can be used to generate event records within the system 10 that identify specific information. The system 10 may process each event with a time/date stamp, the type of event (registration, voice call, text message and other details of the event), along with any electronic hardware identifier (IMEI/ESN/MEID) that is associated with the event, including carrier account identifiers (IMSI, MIN), and the dialed number if applicable. The system 10 may store each event record in the local database such as the event log database 34. The system provides a flexible routing capability that allows the system 10 to route unauthorized device voice call and data access attempts. For example, voice calls could be routed to a standard or custom pre-recorded announcement or to a voice mailbox or even local dialed extension.
Further information could be verified as to the caller to allow the call to be connected or disabled. Data access attempts can be routed to a standard or customized website maintained locally within the facility 44 or can be configured to send traffic to a predefined address on the outside commercial communications network 45. Authorized users are allowed to access outside voice and data networks so their devices can make outside voice calls, send texts, and access content on the internet. This may be authorized by several techniques through the managed access system 10 such as redirecting authorized devices to the commercial communications network 45 and allow them to access the outside voice and data networks. This approach allows an authorized mobile wireless device 42 access to all services provided by their home commercial carrier. Another approach allows all authorized calls through the existing inmate telephone system (ITS), but this approach has privacy concerns for authorized device users.
A preferred technique is to provide voice conductivity through a third party SIP server 242 (
As noted before, each call interaction with a mobile wireless device 42 connected to the managed access system 10 generates an event record within the system 10 that includes the time/date stamp, the type of event such as the registration, voice call, text message and other details along with the hardware identifier and any carrier account identifier that was associated with the event. The system 10 stores each event record in the event log database 34 such as shown in
As noted before, different reports may be generated with the aid of the user interface 30, such as the example screen shots in
The system 10 may also operate in a passive or active mode. In the passive mode, the system 10 allows a mobile wireless device 42 within the coverage area formed by the RF bubble 150 to interact with the system, but does not disrupt access to the commercial communications network 45. It may be used during system verification prior to “going-live.” Once the system 10 is tuned and adjusted, it can be switched over to operate in the active mode where the system attracts and holds cellular and other mobile wireless devices 42 within the facility coverage area. The system 10 prevents those devices from obtaining service from the commercial networks. In this mode, authorized mobile wireless devices 42 are allowed access to voice and data services, while unauthorized devices are not. The active mode would be the normal mode of operation for the system 10.
Because the system 10 has enterprise capability with connection to external communications of a commercial communications network 45, the system 10 is provisioned to log and report event data in customizable ways that make use easy for the operator. In this case, reports, system alerts, emails, and even text messages can be sent and displayed on the graphical user interface 30 when specific events occur. This may include:
1) Health Monitoring: Provides the ability to monitor and view the system health, including status and performance of all major components, equipment alarms, software issues, performance of the servers and web portals.
2) Report Generation: The system also provides the ability to monitor and generate reports on the system performance and threat assessments, create alert logs, audit trails, and long-term activity records. Time and date information are synchronized to the facility logs. Some of the standard reports and alerts are listed below.
Blocked Call Detail Record: Identifies all blocked cellular wireless calls and includes information about the facility from which the call was placed, i.e., date and time, originator's phone number, originator's cellular device hardware ID, and destination phone number (dialed digits). If the optional sensor array is installed, a location estimate is also provided.
User ID Report: Reflects the activity of user ID accounts created/activated during a specific reporting period. This report indicates the name and User ID of the device user that created/activated the account with the date and time stamp, the user account(s) created/activated, the date the profile was deactivated, the last successful or attempted log-in, and all updates to the account.
User ID Alert: Notification of modifications to a device user account.
Audit Log: Provides the User ID, name, log-in date and time, activities (files accessed) for each session. The system also records and reports the user ID, name, time and date of failed attempts.
Authorized Number: Notifies the appropriate operator of the system 10 when a new mobile wireless device 42 has been added or devices have been deleted from the authorized cellular device list. Details the telephone numbers that have been identified as authorized to make calls within the facility. Includes the unique user identifier of the personnel that entered or modified the Authorized Number status as well as the dates of status changes to each number.
Authorized Number Expiration: Provides for authorized cellular wireless device or group of devices due to expire within 30 calendar days.
The system 10 is designed to self-monitor and report the system state of health in order to minimize the operational labor costs. Each functional component of the system 10 is monitored to ensure it is operating normally so the system operates at peak performance. The system 10 verifies communication links to provide a high reliability fault management approach. Any alarm or change in the operating conditions generates a system alert. All alerts are first acknowledged by the appropriate operator prior to the condition being either automatically or manually cleared.
As part of the state of health monitoring 22 (
As noted before, the physical security includes the ability to control physical access to hardware and record and log physical access events. Built-in physical security includes an integrated camera 210 and environmental sensors, including temperature 218, humidity 216, airflow such as smoke 212, door 220, and audio and video recording (
Automated Health Monitoring includes status of the physical (hardware) elements of the system, performance monitoring and metric collection, fault detection and alarms. The status of each line replaceable unit (LRU) is tracked and reported independently, including damaged cables, antennas and sensors.
The system includes an uninterruptable power supply (UPS) 64 (
In order to control costs, any remote LRU's may be connected to protected, back-up power, allowing their continued operation during temporary power outages. The system 10 is also designed to withstand the challenging environment of a correctional institution, if the system 10 is implemented in such a facility. As such, it is not anticipated to require frequent repair from routine damage of wear and tear. Should the system 10 be damaged from events such as lightning strikes, the system provider or installer may be automatically alerted to the event by the state of health monitoring 22 and the system 10 may generate an alert to notify an operator and system provider of the issue.
It is possible that the system 10 may identify and characterize rogue cellular towers using the various sensors and scanners 72, 82, 88, in accordance with a non-limiting example. An example is a rogue fempto cell tower, which is typically a small, low-power cellular base station and connects via broadband such as by DSL or cable to the network 45. Rogue fempto cell towers create threats to the managed access system 10 and will be identified and managed. Other towers may be a newly provisioned commercial service or covertly placed near and network connected. A fempto cell could also be a voice over IP (VoIP) WiFi cell tower or rogue cell tower. The various devices and sensors 72, 82, 88 may use a cellular protocol layer-3 information to identify the existence and location of a rogue cellular tower in near real-time. The sensors 72, 82, 88 identify the operating characteristics of the new and/or rogue cellular towers in sufficient detail to allow the site to be mitigated by the managed access system 10 or they may be investigated by others. It is advantageous over those techniques that authenticate tokens and blacklist, or use a baseband “man-in-the-middle” approach for mitigating threats.
Referring now to
As noted before, the management access server 12 may filter communications between an unauthorized MWD and the network interface device as the in-line IDS monitor and pass communications between an authorized MWD and the network interface device. As noted before, the system is a tiered approach. Unauthorized devices may be held within a “holding pen” where no communications are allowed, and it is possible to deny portions of services and allow the devices to communicate with other authorized or unauthorized devices only in the facility. It is possible to limit outside communications to the device. It is possible to allow the devices to text an SMS message. It is also possible to allow the devices to send alerts and other messages. Thus, the management access server 12 may be configured to permit an unauthorized MWD to communicate with other MWD's at the facility whether unauthorized or authorized depending on how the system is established.
Referring now to
As noted before, the site survey will be used to form a baseline of the existing commercial cell coverage, design distributed antenna system, verify the distributed antenna system 14, and finalize construction. As a non-limiting example, once the system is installed and operational and tuning of the distributed antenna system verified, a Site Acceptance Test (SAT) is completed, which ensures that operational coverage and functionality are acceptable for the facility 44. Table 1 below is an example of the tests and verifications that may be completed for final installation as a non-limiting example.
TABLE 1
Example of High Level Tests and Verification
Key Performance
Success
Determination
Step
Capability
Metrics
Criteria
Methodology
Notes:
1
Operation
System Detects
100%
System
A sample of
Faulted
running.
random LRU's
Hardware
Select any
will be tested
LRU and pull
power,
disconnect
Ethernet
connection,
or remove
optical
connector.
Detect fault
2
Operation
System Detects
100%
System
Temp, Water,
Physical Alarms
running.
Smoke,
and reports
Apply a
Humidity,
event
heater to the
Video, Door
rack temp
Ajar
sensor.
Verify
notification
and log.
Repeat for
other sensors
3
Operation
System Allows
100%
Remotely
Remote Software
flash a new
Upgrades
software load
and verify
new
executable
image loaded
from a
network login
4
Operation
System Allows
100%
Verify GUI
Remote Control
works from
and Status
outside
Monitoring
firewall
5
Operation
System Provides
100%
System
Repeat for each
Tiered User
Running, log
user class
Access levels
in, determine
via System
access and
Sign-on
lock outs
Credentials
6
Electronic
System
95%
System
Multiply by
Threats
Identifies
running. At
All: local
Detection
contraband
selected
technologies ×
cellular phone
locations,
Providers ×
in coverage
turn on
Bands.
area and
Harris
Locations will
reports
provided test
be determined
contraband
by applying a
cellular
10 wide × 10
phones.
long grid
Verify
across coverage
registration
area and
and event
selecting test
logs
points within
each grid
sector
7
Electronic
System Provides
100%
System
Multiply by
Threats
Logs of
running,
All: local
Detection
detected device
invoke
technologies ×
events
events, view
Providers ×
logs
Bands.
Locations will
be determined
by applying a
10 wide × 10
long grid
across coverage
area and
selecting test
points within
each grid
sector
8
Electronic
System Provides
TBD
System
Each protected
Threats
Localization of
meters
running,
building will
Detection
User Equipment
invoke
be tested at
in Covered Area
contraband
evenly
to within (If
cellular
distributed
option
phone, view
test points.
implemented)
GUI report
10-
points/building
9
Interdictions
System
95%
System
Multiply by
Interdicts
running, turn
All: local
contraband
on contraband
technologies ×
cellular phone
cellular
Providers ×
voice calls and
phone in
Bands.
reports event
coverage
Locations will
area, verify
be determined
no service at
by applying a
cellular
10 wide × 10
phone
long grid
across coverage
area and
selecting test
points within
each grid
sector
10
Interdictions
System
95%
System
Multiply by
Interdicts
running, send
All: local
cellular phone
SMS from
technologies ×
Generated SMS
contraband
Providers ×
Messages and
phone, verify
Bands.
reports event
no SMS sent
Locations will
be determined
by applying a
10 wide × 10
long grid
across coverage
area and
selecting test
points within
each grid
sector
11
Interdictions
System provides
95%
System
Multiply by
graphic
running,
All: local
representation
invoke
technologies ×
of localized
contraband
Providers ×
cellular phone
cellular
Bands.
on
phone, locate
Locations will
representative
on site map
be determined
map of coverage
by applying a
area
10 wide × 10
long grid
across coverage
area and
selecting test
points within
each grid
sector
12
Interdictions
System
95%
System
Multiply by
prevents
running, call
All: local
incoming voice
a contraband
technologies ×
calls to
cellular
Providers ×
contraband
phone number
Bands.
cellular phones
hosted in
Locations will
in coverage
covered area,
be determined
area
verify no
by applying a
call
10 wide × 10
completed
long grid
across coverage
area and
selecting test
points within
each grid
sector
13
Interdictions
System prevents
95%
System
Multiply by
delivery of
within 1
running, SMS
All: local
SMS messages to
hr
message
technologies ×
contraband
powered
Providers ×
cellular phones
contraband
Bands.
in coverage
cellular
Locations will
area
phone in
be determined
covered area
by applying a
from outside
10 wide × 10
cellular
long grid
phone, verify
across coverage
no SMS
area and
delivered
selecting test
over 1 hour
points within
each grid
sector
14
Access
System Provides
95%
System
Multiply by
management
cellular phone
running, turn
All: local
initiated Voice
on authorized
technologies ×
Service to
cellular
Providers ×
authorized
phone in
Bands.
users and
coverage
Locations will
reports event
area, verify
be determined
voice service
by applying a
at cellular
10 wide × 10
phone
long grid
across coverage
area and
selecting test
points within
each grid
sector
15
Access
System Provides
95%
System
Multiply by
management
911 from any
running, dial
All: local
cellular phone
911 from
technologies ×
in coverage
cellular
Providers ×
area and
phone in
Bands.
forwards to
coverage
Locations will
specified
area, verify
be determined
cellular phone
rings through
by applying a
and reports
to specified
10 wide × 10
event
cellular
long grid
phone
across coverage
area and
selecting test
points within
each grid
sector
16
Access
System
95%
System
Multiply by
management
facilitates
running, SMS
All: local
delivery
message
technologies ×
incoming SMS
powered
Providers ×
Service to
authorized
Bands.
authorized
cellular
Locations will
cellular phones
phone in
be determined
and reports
covered area,
by applying a
event
verify SMS
10 wide × 10
delivered
long grid
across coverage
area and
selecting test
points within
each grid
sector
17
Access
System
95%
System
Multiply by
management
facilitates
running, SMS
All: local
delivery of
message sent
technologies ×
SMS Service
from powered
Providers ×
from authorized
authorized
Bands.
cellular phone
cellular
Locations will
and reports
phone in
be determined
event
covered area,
by applying a
verify SMS
10 wide × 10
delivered
long grid
across coverage
area and
selecting test
points within
each grid
sector
18
Access
System does not
95%
System
Multiply by
management
interfere with
running,
All: local
commercial
verify OEM
technologies ×
cellular
service
Providers ×
service outside
outside of
Bands.
the property
property
Locations will
boundary of the
boundary
be determined
facility
by applying a
10 wide × 10
long grid
across coverage
area and
selecting test
points within
each grid
sector
Once the physical site survey is accomplished as explained above, engineers can determine site specific data such as power and cooling requirements for equipment, any cable routing access, any access and power requirements, and any antenna locations and similar details. Engineers may determine specifics relating to local or state building codes and issues relating to site (customer) specific permitting. Existing underground utilities may be identified and any other cables tested prior to being energized, including existing and new voltage, fiber optic or Ethernet cables.
As noted before, the managed access system 10 monitors and generates reports for system performance and threat assessments such as alert logs, audit trails, and long-term activity records. These reports can be standardized. Possible reports could include a blocked call detail record that identifies all blocked cellular wireless calls and includes information about the facility from which the call was placed, its date and time, the originator's phone number, the originator's cellular device hardware identifier (ID), and the destination phone number as the dialed digits.
A user ID report may reflect the activity of user ID accounts created and activated during a specific reporting period. This report may indicate the name and user ID of a user that created or activated the account with the date and time stamp and the user accounts that were created or activated and the date the profile was deactivated as well as the last successful or attempted log-in. Information regarding the creation, modification and deletion of a user account may be generated. An audit log report may provide the user ID, name, log-in date and time, activities with the files accessed for each session, and the records and reports for the user ID, name, time and date of failed attempts.
An authorized number alert report may be generated to notify an appropriate operator when a new mobile wireless device 42 has been added or mobile wireless devices deleted from the authorized device list. Authorized number reports may detail the telephone numbers that have been identified as authorized to make calls within the facility 44. This report may include the unique identifier of a user that entered or modified the authorized number status and the dates of status changes to each number. Expiration reports may be provided for authorized cellular wireless device or groups of devices due to expire within 30 calendar days as a non-limiting example.
Software CSCI (Computer Software Configuration Items) are now described with reference to
The MAS main application CSCI 308 is shown in
The network manager 316 shown in
The surveyor manager 318 will initiate periodic surveys of surrounding cellular towers and the survey results are stored in the local coverage database 26 (
Referring now to
The web server 302 serves the web application and supports multiple simultaneous operators. As shown in
This application is related to copending patent applications entitled, “MANAGED ACCESS SYSTEM WITH MONITORING DEVICE TO DETERMINE SYSTEM OPERABILITY,” now U.S. Publication No. 2017-0094534 published Mar. 30, 2017, and “MANAGED ACCESS SYSTEM THAT DETERMINES AUTHORIZED AND UNAUTHORIZED MOBILE WIRELESS DEVICES,” now U.S. Publication No. 2017-0094520 published Mar. 30, 2017, and “MANAGED ACCESS SYSTEM HAVING FILTERED COMMUNICATIONS USING NETWORK INTERFACE DEVICE,” now U.S. Publication No. 2017-0094521 published Mar. 30, 2017, and U.S. Pat. No. 9,584,252 issued Feb. 28, 2017, entitled, “MANAGED ACCESS SYSTEM WITH MOBILE WIRELESS DEVICE GEOLOCATION CAPABILTY,” each which was filed on the same date and by the same Assignee, the disclosures which are hereby incorporated by reference.
Many modifications and other embodiments of the invention will come to the mind of one skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is understood that the invention is not to be limited to the specific embodiments disclosed, and that modifications and embodiments are intended to be included within the scope of the appended claims.
Gallagher, Shawn H., Salyers, Eric J., Collins, Matthew D.
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